Surgical Instrument with Non-Contact Electrical Coupling

ABSTRACT

A surgical instrument includes a reusable base component including a handle and an electrically activatable modular component removably coupled to the base component. The modular component includes an end effector operable from the handle to treat tissue. The end effector is responsive to manipulation of the handle. A first energy storage component is disposed onboard the base component and is electrically coupled to a source of electricity. A second energy storage component is disposed onboard the modular component and is electrically insulated from the first energy storage component. The second energy storage component is arranged such that a current may be selectively induced in the modular component by delivery of electrical energy to the first energy storage component.

BACKGROUND

1. Technical Field

The present disclosure relates generally the field of reusable surgicalinstruments. In particular, the disclosure relates electrical couplingsfor instruments having separable and replaceable components to provideclean, sterile or refurbished surfaces in each instance of use.

2. Background of Related Art

Instruments such as electrosurgical forceps are commonly used in openand endoscopic surgical procedures to coagulate, cauterize and sealtissue. Such forceps typically include a pair of jaws that can becontrolled by a surgeon to grasp targeted tissue, such as, e.g., a bloodvessel. The jaws may be approximated to apply a mechanical clampingforce to the tissue, and are associated with at least one electrodesurface to permit the delivery of electrosurgical energy to the tissue.The combination of the mechanical clamping force and the electrosurgicalenergy has been demonstrated to join adjacent layers of tissue capturedbetween the jaws. When the adjacent layers of tissue include the wallsof a blood vessel, sealing the tissue may result in hemostasis.Thereafter, the sealed tissue may be transected by advancing a knifethrough the jaws. A detailed discussion of the use of an electrosurgicalforceps may be found in U.S. Pat. No. 7,255,697 to Dycus et al.

In use, various tissue-contacting components of an electrosurgicalforceps tend to become contaminated or degraded. For example, electrodesmay become contaminated as portions of the treated tissue adhere to thetissue-contacting surfaces of the electrodes. Also, a knife blade maybecome dull and less effective in transecting sealed tissue afterrepeated use, even in a single surgical procedure. In order to provideclean electrodes and a sharp knife for a particular surgical procedure,a brand new instrument is often used. Once the procedure is complete,the used instrument is discarded.

Instruments that are reusable for multiple procedures reduce theinstrumentation costs per procedure. Some reusable forceps include areusable component adapted for persistent use coupled to a removable andreplaceable component adapted for limited use. The reusable componentmay include, for example, a control element such as a handle thatremains primarily outside the surgical field. The handle may beconstructed ruggedly to sustain regular and recurring usage in numeroussurgical procedures. The removable and replaceable component may includea tool element, such as an end effector containing the delicate andtissue-contacting wear surfaces. Replacing a worn end effector torefurbish an instrument provides refreshed surfaces with minimal waste.

Providing replaceable components for a reusable electrosurgical forceps,however, presents various challenges. For example, many of theseinstruments require arduous disassembly and reassembly procedures toensure proper electrical continuity is provided between the reusable andreplaceable components. Also, electrical couplings on the reusablecomponent may be difficult to clean.

SUMMARY

The present disclosure describes a surgical instrument for treatingtissue. The instrument includes a reusable base component with a handleassembly and an electrically-activated modular component removablycoupled to the base component. The modular component includes an endeffector operable from the handle assembly to treat tissue, and the endeffector is responsive to manipulation of the handle assembly to movebetween first and second configurations. A first energy storagecomponent is disposed onboard the base component, and the first energystorage component is electrically coupled to a source of electricity. Asecond energy storage component is disposed onboard the modularcomponent. The second energy storage component is electrically insulatedfrom the first energy storage component and is arranged with respect tothe first energy storage component such that a current may beselectively induced in the modular component by delivery of electricalenergy to the first energy storage component.

The first energy storage component may include a first inductive coiland the second energy storage component may include a second inductivecoil. The second inductive coil may be inductively coupled to the firstinductive coil such that a current is induced in the second coil inresponse to a current flow in the first coil.

The source of electricity may be an electrosurgical generator, and themodular component may include at least one electrode. The electrode maybe electrically coupled to the second coil and configured for deliveringelectrosurgical energy to tissue.

The modular component may include pair of opposing jaw members, and oneor both of the jaw member may be movable between an open configurationwherein the jaw members are substantially spaced for receiving tissueand a closed configuration wherein the jaw members are closer togetherfor clamping tissue therebetween. The end effector may include a sensorfor detecting a parameter of the tissue treatment, and the sensor may bepowered by the induced current in the second coil. The sensor may be agap sensor configured to detect a separation distance between theopposing jaw members.

The first energy storage component may include a first capacitor havinga pair of conductive plates separated by a dielectric material. Thesecond energy storage component may include a second capacitor having apair of conductive plates arranged on opposite sides of the firstcapacitor. Each of the conductive plates of the second capacitor may beseparated from a conductive plate of the first capacitor by a dielectricmaterial. The conductive plates of the second capacitor may be arrangedon a respective opposing jaw member.

According to another aspect of the disclosure, a modular end effectorfor a surgical instrument includes an electrically-activated componentand an inductor coil electrically coupled to the electrically-activatedcomponent. The end effector includes a contactless mechanical interfaceconfigured to removably couple the end effector to a correspondinginterface on a base component of the surgical instrument. The mechanicalinterface is electrically isolated from the electrically-activatedcomponent.

The end effector may include a pair of opposing jaw members, and one orboth of the jaw members may be movable between an open configurationwherein the jaw members are substantially spaced for receiving tissueand a closed configuration wherein the jaw members are closer togetherfor clamping tissue therebetween. The electrically-activated componentmay include an electrode disposed on an opposed clamping surface of oneof the jaw members, and the contactless mechanical interface may includea linkage for receiving reciprocal motion from the base component. Thelinkage may be operable to move the at least one of the pair of jawmembers between the open configuration and the closed configuration.

According to another aspect of the disclosure, a surgical instrumentincludes a reusable base component with a handle assembly and anelongated tube extending distally from the handle assembly. Anelectrically-activated modular component is removably coupled to thebase component, and the modular component includes a pair of jaw membersoperable from the handle assembly and configured to move between an openconfiguration wherein the jaw members are substantially spaced forreceiving tissue and a closed configuration wherein the jaw members arecloser together for clamping tissue. A first capacitor plate isoperatively associated with the elongated tube, and a second capacitorplate is operatively associated with one of the jaw members. The secondcapacitor plate forms a capacitor with the first capacitor plate tocapacitively couple the base component and the modular component.

The first capacitor plate may be electrically coupled to a source ofelectrosurgical energy, the second capacitor plate may be electricallycoupled to an electrode configured to deliver the electrosurgical energyto tissue. A pair of capacitor plates may be operatively associated withthe elongated tube, and each of the jaw members may include a capacitorplate forming a respective capacitor with a respective capacitor plateof the elongated tube.

The one of the jaw members may include a pair of capacitor platesstraddling the first capacitor plate on the elongated tube. The pair ofcapacitor plates of the one of the jaw members may define legs of agenerally U-shaped conductive portion of the first jaw member.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate embodiments of the presentdisclosure and, together with the detailed description of theembodiments given below, serve to explain the principles of thedisclosure.

FIG. 1 is a perspective view of an endoscopic surgical instrument inaccordance with an embodiment of the present disclosure having modularjaw members inductively coupled to a distal end of an elongated shaft;

FIG. 2 is an enlarged, perspective view of a distal end of theinstrument of FIG. 1 depicting the modular jaw members separated fromthe elongated shaft;

FIG. 3 is a perspective view of an alternate embodiment of an instrumentin accordance with the present disclosure having a modular end effectorseparated from an elongated shaft;

FIG. 4A is a perspective view of an alternate embodiment of aninstrument in accordance with the present disclosure having modular jawmembers for capacitive coupling with an elongated shaft;

FIG. 4B is a cross-sectional view of the modular jaw members of FIG. 4Acapacitively coupled to the elongated shaft;

FIG. 4C is a schematic view of a current path through tissue capturedbetween the modular jaw members of FIG. 4A;

FIG. 5 is a perspective view of an alternate embodiment of modular jawmembers configured for capacitive coupling with an elongated shaftwherein multiple plates are employed; and

FIG. 6 is an alternate embodiment of a surgical instrument in accordancewith the present disclosure configured for use in open surgicalprocedures.

DETAILED DESCRIPTION

Referring initially to FIG. 1, an embodiment of an electrosurgicalinstrument 10 is depicted. The instrument 10 includes a handle assembly12, an end effector 14 and an elongated shaft 16 therebetween. A surgeonmay manipulate the handle assembly 12 to remotely control the endeffector 14 through the elongated shaft 16. This configuration istypically associated with instruments for use in laparoscopic orendoscopic surgical procedures. Various aspects of the presentdisclosure may also be practiced with traditional open instruments (seeFIG. 5), and in connection with endoluminal procedures as well.

The instrument 10 is coupled to a source of electrosurgical energy,e.g., an electrosurgical generator 18. The generator 18 may includedevices such as the LIGASURE™ Vessel Sealing Generator and the ForceTriad™ Generator as sold by Covidien. A cable 20 extends between thehandle assembly 12 and the generator 18, and includes a connector 22 forcoupling the instrument 10 to the generator 18. The connector 22includes two prong members 22 a and 22 h that are dimensioned tomechanically and electrically connect the instrument 10 to oppositeterminals, e.g., positive or active (+) and negative or return (−)terminals associated with the generator 18. Thus, bipolar energy may beprovided through the instrument 10. Alternatively, the instrument 10 maybe configured for delivering monopolar energy to the tissue. In amonopolar configuration, the instrument 10 delivers electrosurgicalenergy from an active terminal, e.g. (+), while a return pad (not shown)is placed generally beneath a patient and provides a return path to theopposite terminal, e.g. (−), of the generator 18.

To control the end effector 14, the handle assembly 12 includes astationary handle 24 and movable handle 26. The movable handle 26 may beseparated and approximated relative to the stationary handle 24 torespectively open and close the end effector 14. A trigger 30 is alsodisposed on the handle assembly 12, and is operable to extend andretract a knife 76 (FIG. 3) through the end effector 14. A footswitch(not shown) may be provided to initiate and terminate the delivery ofelectrosurgical energy to the end effector 14.

Referring now to FIG. 2, end effector 14 includes upper and lower jawmembers 32 and 34. Each of the modular jaw members 32, 34 is coupled tothe elongated shaft 16 about a pivot pin 36. The jaw members 32, 34include respective proximal flanges 38, 40 extending into a bifurcateddistal end of the elongated shaft 16, where a respective bore 38 a, 40 aengages the pivot pin 36. The proximal flanges 38, 40 are operativelyassociated with the movable handle 26 (FIG. 1) to open and close the jawmembers 32, 34. The jaw members 32, 34 are movable between an openconfiguration where the jaw members 32, 34 are substantially spaced toreceive tissue and a closed configuration where the jaw members 32, 34are closer together to clamp the tissue therebetween. Retraction of themovable handle 26 induces the jaw members 32, 34 to move to the openconfiguration and separation of the movable handle 26 from thestationary handle 24 induces the jaw members 32, 34 to move to theclosed configuration.

Various mechanisms may be provided to operatively associate the movablehandle 26 with the proximal flanges 38, 40. For example, the movablehandle 26 may be coupled to a reciprocating member (not shown) thatextends through the elongated shaft 16 as described in commonly ownedU.S. Pat. No. 7,255,697 to Dycus et al. The reciprocating member mayengage cam slots (not shown) on each of the proximal flanges 38, 40 tochange the position of both of the jaw members 32, 34 relative to theelongated shaft. This type of construction induces bilateral jaw motion.Other unilateral constructions are also envisioned in which only one jawmember 32, 34 moves with respect to the elongated shaft.

When clamped about tissue, the jaw members 32, 34 may deliverelectrosurgical energy to the tissue through a pair of opposedelectrodes 42, 44. The electrodes 42, 44 are configured to selectivelyapply an effective amount of pressure and electrosurgical energy to thetissue. The opposed electrodes are associated with opposite electricalpotentials (+), (−) to permit an electrosurgical current to flow throughthe tissue situated between the jaw members 32, 34 to effect a tissueseal.

The modular jaw members 32 and 34 are selectively removable from theelongated shaft 16 to facilitate replacement the jaw members 32, 34following a surgical procedure. Replacement of the jaw members 32, 34may serve to refurbish the instrument 10 for subsequent use. The pivotpin 36 may be spring loaded to retain the flanges 38 and 40 within thebifurcated distal end of the elongated shaft 16 when the instrument 10is in use. Following an electrosurgical procedure, the spring loadedpivot pin 36 may be manipulated to release the used jaw members 32, 34without requiring a cumbersome disassembly process. Thereafter, thepivot pin 36 may snap into a set of bores 38 a, 40 a of a clean, new orrefurbished set of jaw members 32, 34.

In the illustrated embodiment, when the jaw members 32, 34 are connectedto the elongated shaft, a contactless electrical coupling isestablished. The proximal flange 40 of lower jaw member 34 isinductively coupled to the elongated shaft 16 through a pair of spiralcoils 48, 52. The spiral coils 48, 52 form inductors, which store energyby generating a magnetic field when an electrical current is passedtherethrough. The first coil 48 is disposed onboard the elongated shaft16, which forms part of a reusable base component of the instrument 10.The first coil 48 is electrically coupled to the two prongs 22 a, 22 bof the connector 22 (FIG. 1) through respective lead wires 48 a, 48 bextending through the instrument 10. The two lead wires 48 a, 48 b maybe associated with the opposite electrical potentials of the prongs 22 a(+), 22 b (−) The second coil 52 is disposed on board the modular jawmember 34, which forms a replaceable component of the instrument 10. Thesecond coil 52 is electrically coupled to the two electrodes 42 (+) and44 (−) of opposite electrical potential.

The coils 48, 52 are constructed of an appropriate electricallyconductive material, such as copper or stainless steel wire. The coils48, 52 are separated by an electrically insulative material such that nodirect contact exists between the coils 48, 52. One or both of theelongated shaft 16 and the proximal flange 40 of the lower jaw member 34may be constructed of an insulative material such as a ceramic orreinforced plastic that contains the respective coil 48, 52. Theinsulative material protects the coils 48, 52 from mechanical damage,and may form a flat interface on the exterior of the respectivecomponent 16, 40 that may be cleaned without undue difficulty.

The coils 48, 52 are arranged such that when the lower jaw member 34 isinstalled, the coils 48, 52 are axially aligned, and face-to-face inparallel planes. The two coils 48, 52 are spatially as close to oneanother as is practical since inductive coupling is most effective atshort distances. In use, a current is supplied by the electrosurgicalgenerator 18 (FIG. 1) to the first coil 48. The current in the firstcoil 48 generates a magnetic field passing through the second coil 52.The magnetic field induces a current in the second coil 52 that is usedto power the electrodes 42, 44.

Referring now to FIG. 3, an alternate embodiment of an instrument 60includes a reusable base component 62 and a removable modular component64. The base component 62 includes a first elongated shaft portion 66 aextending from a handle assembly 12 (see FIG. 1), and the modularcomponent 64 includes a second elongated shaft component 66 b extendingto an end effector 68. The two elongated shaft portions 66 a, 66 b maybe mechanically fastened to one another to permit mechanical motion ofjaw members 72, 74 between open and closed configurations andadvancement and retraction of an optional reciprocating knife blade 76through the lower jaw member 74.

Advancement of the reciprocating knife 76 permits the transaction oftissue, particularly once the tissue has been sealed. To facilitate themechanical motion of the jaw members 72, 74 and/or the knife blade 76,the modular component 64 includes a first linkage 77 a for receivingreciprocal motion from a corresponding second linkage 77 b on the basecomponent 62. The first linkage 77 a may be directly coupled to theknife 76 such that reciprocal motion of the first linkage 77 a induces acorresponding reciprocal motion in the knife 76. Alternatively oradditionally, the reciprocal motion of the first linkage may beconverted to pivotal motion of the jaw members 72, 74 through the use ofcam surfaces (not shown) or other conventional mechanisms. The secondlinkage 77 b extends to the handle assembly 12 (FIG. 1) and may receivereciprocal motion therefrom.

An electrical coupling between the modular component 64 and the basecomponent 62 may be established by inductive coupling. The basecomponent 62 includes a first coil 78 electrically coupled to theopposite poles of electrosurgical generator 18 (FIG. 1). The modularcomponent includes a second coil 80 that may be coupled to electrodes 82and 84. First and second coils 78, 80 are longitudinally arranged inrespective elongated shaft portions 66 a, 66 b. The elongated shaftportions 66 a, 66 b provide ample length for a significant number ofcoils. The coils 78, 80 are laterally separated from one another. Otherconfigurations are envisioned, such as a coaxial configuration whereinone coil is situated longitudinally within the other. This type ofelectrical coupling permits a contactless mechanical interface to beestablished between the removable component 64 and the base component62. The mechanical interface may be contactless in that electricity isnot transmitted through any of the mechanically engaging surfaces suchthat the mechanical interface is electrically isolated from theelectrodes 82, 84.

In addition to the electrodes 82, 84, other electrical devices may beincluded on the modular component 64 to be powered by a current flowingthrough the second coil 80. For example, a gap sensor 86 is included onthe lower jaw member 74. The gap sensor 86 is configured to sense theseparation or “gap distance” between the jaw members 72, 74. Anappropriate gap distance for generating an effective tissue seal may bebetween about 0.001 inches and about 0.006 inches. A gap distancebetween about 0.002 inches and about 0.003 inches may be preferred insome instances. The gap sensor 86 may include any suitable sensor suchas optical sensor, and may receive power and communicate data with theelectrosurgical generator 18 through the inductive coupling. Anappropriate gap sensor is described in commonly owned U.S. PatentApplication Publication No. 2009/0204114 to Odom.

Referring now to FIG. 4A, an alternate embodiment of an instrument 100includes modular jaw members 102, 104 configured for non-contact,capacitive coupling with a base component 106. The base component 106includes a pair of electrically conductive plates 110 a, 110 b disposedat a distal end of an elongated shaft 112. The plates 110 a, 110 b arecoupled to the electrosurgical generator 18 (FIG. 1) such that a firstconductive plate 110 a is coupled to a first terminal of the generator,e.g. active (+), and a second conductive plate 110 b is coupled to asecond terminal, e.g. return (−). The conductive plates 110 a, 110 b areseparated by an electrically insulative, dielectric material 114. A pairof dielectric plates 116 a and 116 b are disposed laterally exterior tothe conductive plates 110 a, 110 b.

A proximal flange 118 of the upper jaw member 102 includes a flat-plateelectrically conductive portion 120 adjacent a structural body portion122. Similarly, a proximal flange 124 of the lower jaw member 104includes a flat-plate electrically conductive portion 126 adjacent astructural body portion 128. The conductive plate portions 120, 126 arein electrical communication with respective electrodes 132, 134.

The modular jaw members 102, 104 may be assembled to the base component106 as depicted in FIG. 4B. The distal end of elongated shaft 112 isinterposed between the electrically conductive plates 120, 126 of thejaw members 102, 104. The dielectric plate 116 a is interposed betweenconductive plates 110 a and 120 to define a first parallel platecapacitor 136. The conductive plate 120 of the upper jaw member 102 maythus be capacitively coupled to the base component 106. The dielectricplate 116 b is similarly interposed between conductive plates 110 b and126 to define a second capacitor 138. The conductive plate 126 of thelower jaw member 104 may thus be capacitively coupled to the basecomponent 106.

When the modular jaw members 102, 104 are assembled to the basecomponent 106 and tissue “t” is captured between the electrodes 132,134, an electrosurgical current “I” may be induced through the tissue“t” as indicated in FIG. 4C. Electrosurgical energy, such aselectrosurgical current “I” at a predetermined output frequency andpower may pass from a first terminal, e.g. an active terminal (+), ofthe generator 18 through the first capacitor 136 to upper jaw member102. The current “I” is transmitted through the active electrode 132 andthe tissue “t” to return electrode 134. The current “I” returns throughsecond capacitor 138 to a second terminal, e.g., a return terminal (−),of the generator 18.

Referring now to FIG. 5, an alternate embodiment of a modular jaw member152 is configured for capacitive coupling to a base shaft 154. Themodular jaw member 154 includes an electrically conductive plate 156 andan electrically conductive U-shaped portion 158 having a pair ofgenerally flat legs or plates 158 a and 158 b. The conductive plate 156and U-shaped portion 158 are disposed in an insulative structural bodyportion 160, and may be electrically coupled to an electrode (not shown)configured to deliver electrosurgical energy to tissue. The base shaft154 includes first and second conductive plates 162, 164 eachelectrically coupled to an active terminal (+) of electrosurgicalgenerator 18. The conductive plates 162, 164 are disposed in aninsulative body portion 166.

The modular jaw member 152 may be assembled to the base shaft 154 suchthat the U-shaped portion 158 of jaw member 152 straddles the firstconductive plate 162 of the shaft 164. In the assembled configuration,the first conductive plate 162 of the shaft 154 forms a parallel platecapacitor with each of the legs 158 a, 158 b of the U-shaped portion158. Additionally, the second conductive plate 164 of the shaft 154forms a parallel plate capacitor with conductive plate 156 of themodular jaw member 152.

A similar construction may be defined for an opposing jaw member (notshown) configured for capacitive coupling to a return terminal (−), ofthe generator 18. Since each of the terminals (+), (−) of the generator18 are capacitively coupled a respective jaw member, e.g., jaw member152, through plates, e.g., 156, 158 a, 158 b, 162, 164 forming multiplecapacitors, a greater current may be induced through tissue.

With regard to FIG. 6, a forceps 200 configured for use in various opensurgical procedures may also incorporate many of the features describedabove. Forceps 200 includes a pair of opposing elongated shafts 212 aand 212 b having an end effector assembly 230 attached to the distalends 216 a and 216 b thereof, respectively. End effector assembly 230 issimilar in design to end effector assembly 14 described above withreference to FIG. 1. End effector assembly 230 includes pair of opposingjaw members 232 and 234 that are pivotably connected about a pivot pin265, and which are movable relative to one another to grasp tissue.

Each shaft 212 a and 212 b includes a handle 215 and 217, respectively,disposed at the proximal end 214 a and 214 b thereof which each define afinger hole 215 a and 217 a, respectively, therethrough for receiving afinger of the clinician. Finger holes 215 a and 217 a facilitatemovement of the shafts 212 a and 212 b relative to one another which, inturn, pivot the jaw members 232 and 234 from an open position whereinthe jaw members 232 and 234 are disposed in spaced relation relative toone another to a clamping or closed position wherein the jaw members 232and 234 cooperate to grasp tissue therebetween.

An electrosurgical cable 268 couples the instrument 200 to a source ofelectrosurgical energy, and conductive pathways 270 are provided totransmit electrosurgical energy to the jaw members 232, 234. A knifetrigger 280 is provided to induce a knife (not shown) to transect tissuecaptured between the jaw members 232, 234.

The jaw members 232 and 234 may be configured as modular and selectivelyremovable components separable from the rest of the forceps 200. The jawmembers may be coupled with a contactless electrical interface asdescribed above to connect the jaw members 232, 234 to the conductivepathways 270. For example, an inductive coupling as described above withreference to FIGS. 2 and 3 may be provided, or a capacitive couplinginterface as described above with reference to FIGS. 4A and 4B may beselected.

Although the foregoing disclosure has been described in some detail byway of illustration and example, for purposes of clarity orunderstanding, it will be obvious that certain changes and modificationsmay be practiced within the scope of the appended claims.

1. A surgical instrument, comprising: a reusable base component, thebase component including a handle assembly; an electrically-activatedmodular component removably coupled to the base component, the modularcomponent including an end effector operable from the handle assembly totreat tissue, the end effector responsive to manipulation of the handleassembly to move between first and second configurations; a first energystorage component disposed onboard the base component, the first energystorage component electrically coupled to a source of electricity; and asecond energy storage component onboard the modular component, thesecond energy storage component electrically insulated from the firstenergy storage component and arranged with respect to the first energystorage component such that a current may be selectively induced in themodular component by delivery of electrical energy to the first energystorage component.
 2. The surgical instrument according to claim 1,wherein the first energy storage component includes a first inductivecoil and the second energy storage component includes a second inductivecoil, and wherein the second inductive coil is inductively coupled tothe first inductive coil such that a current is induced in the secondcoil in response to a current flow in the first coil.
 3. The surgicalinstrument according to claim 2, wherein the source of electricity is anelectrosurgical generator.
 4. The surgical instrument according to claim3, wherein the modular component includes at least one electrodeelectrically coupled to the second coil, the electrode configured fordelivering electrosurgical energy to tissue.
 5. The surgical instrumentaccording to claim 4, wherein the modular component includes pair ofopposing jaw members, wherein at least one of the pair of jaw members ismovable between an open configuration wherein the jaw members aresubstantially spaced for receiving tissue and a closed configurationwherein the jaw members are closer together for clamping tissuetherebetween.
 6. The surgical instrument according to claim 5, whereinthe end effector includes a sensor for detecting a parameter of thetissue treatment, and wherein the sensor is powered by the inducedcurrent in the second coil.
 7. The surgical instrument according toclaim 6, wherein the sensor is a gap sensor configured to detect aseparation distance between the opposing jaw members.
 8. The surgicalinstrument according to claim 1, wherein the first energy storagecomponent includes a first capacitor having a pair of conductive platesseparated by a dielectric material, and wherein the second energystorage device includes a second capacitor having a pair of conductiveplates arranged on opposite sides of the first capacitor, each of theconductive plates of the second capacitor separated from a conductiveplate of the first capacitor by a dielectric material.
 9. The surgicalinstrument according to claim 8, wherein each of the conductive platesof the second capacitor are arranged on a respective opposing jawmember.
 10. A modular end effector for a surgical instrument,comprising: an electrically-activated component; an inductor coilelectrically coupled to the electrically-activated component; and acontactless mechanical interface configured to removably couple the endeffector to a corresponding interface on a base component of thesurgical instrument, the mechanical interface electrically isolated fromthe electrically-activated component.
 11. The end effector according toclaim 10, further comprising a pair of opposing jaw members, wherein atleast one of the pair of jaw members is movable between an openconfiguration wherein the jaw members are substantially spaced forreceiving tissue and a closed configuration wherein the jaw members arecloser together for clamping tissue therebetween.
 12. The end effectoraccording to claim 11, wherein the electrically-activated componentincludes an electrode disposed on an opposed clamping surface of one ofthe jaw members.
 13. The end effector according to claim 10, wherein thecontactless mechanical interface includes a linkage for receivingreciprocal motion from the base component, the linkage operable to movethe at least one of the pair of jaw members between the openconfiguration and the closed configuration.
 14. A surgical instrument,comprising: a reusable base component, the base component including ahandle assembly and an elongated tube extending distally therefrom; anelectrically-activated modular component removably coupled to the basecomponent, the modular component including a pair of jaw membersoperable from the handle assembly and configured to move between an openconfiguration wherein the jaw members are substantially spaced forreceiving tissue and a closed configuration wherein the jaw members arecloser together for clamping tissue therebetween; a first capacitorplate operatively associated with the elongated tube; and a secondcapacitor plate operatively associated with one of the jaw members, thesecond capacitor plate forming a capacitor with the first capacitorplate to capacitively couple the base component and the modularcomponent.
 15. The surgical instrument according to claim 14, whereinthe first capacitor plate is electrically coupled to a source ofelectrosurgical energy, and wherein the second capacitor plate iselectrically coupled to an electrode configured to deliver theelectrosurgical energy to tissue.
 16. The surgical instrument accordingto claim 14, wherein a pair of capacitor plates is operativelyassociated with the elongated tube, and wherein each of the jaw membersincludes a capacitor plate disposed thereon forming a respectivecapacitor with a respective capacitor plate of the elongated tube. 17.The surgical instrument according to claim 14, wherein the one of thejaw members includes a pair of capacitor plates disposed thereonstraddling the first capacitor plate.
 18. The surgical instrumentaccording to claim 17, wherein the pair of capacitor plates of the oneof the jaw members define legs of a generally U-shaped conductiveportion of the first jaw member.